Study of local protein synthesis in growth cones of embryonic mouse motor neurons / Analyse der lokalen Proteinsynthese in Wachstumskegeln von embryonalen Maus Motoneuronen

Rathod, Reenaben Jagdishbhai

January 2012

In cultured motoneurons of a mouse model for the motoneuron disease spinal muscular atrophy (SMA), reduced levels of the protein SMN (survival of motoneurons) cause defects in axonal growth. This correlates with reduced β-actin mRNA and protein in growth cones, indicating that anterograde transport and local translation of β-actin mRNA are crucial for motoneuron function. However, direct evidence that indeed local translation is a physiological phenomenon in growth cones of motoneurons was missing. Here, a lentiviral GFP-based reporter construct was established to monitor local protein synthesis of β-actin mRNA. Time-lapse imaging of fluorescence recovery after photobleaching (FRAP) in living motoneurons revealed that β-actin is locally translated in the growth cones of embryonic motoneurons. Interestingly, local translation of the β-actin reporter construct was differentially regulated by different laminin isoforms, indicating that laminins provide extracellular cues for the regulation of local translation in growth cones. Notably, local translation of β-actin mRNA was deregulated when motoneurons of a mouse model for type I SMA (Smn-/-; SMN2) were analyzed. In situ hybridization revealed reduced levels of β-actin mRNA in the axons of Smn-/-; SMN2 motoneurons. The distribution of the β-actin mRNA was not modified by different laminin isoforms as revealed by in situ hybridization against the mRNA of the eGFP encoding element of the β-actin reporter. In case of the mRNA of α-actin and γ-actin isoforms, the endogenous mRNA did not localize to the axons and the localization pattern was not affected by the SMN levels expressed in the cell. Taken together our findings suggest that regulation of local translation of β-actin in growth cones of motoneurons critically depends on laminin signaling and the amount of SMN protein. Embryonic stem cell (ESC)-derived motoneurons are an excellent in vitro system to sort out biochemical and cellular pathways which are defective in neurodegenerative diseases like SMA. Here, a protocol for the differentiation and antibody-mediated enrichment of ESC-derived motoneurons is presented, which was optimized during the course of this study. Notably, this study contributes the production and purification of highly active recombinant sonic hedgehog (Shh), which was needed for the efficient differentiation of mouse ESCs to motoneurons. ESC-derived motoneurons will now offer high amounts of cellular material to allow the biochemical identification of disease-relevant molecular components involved in regulated local protein synthesis in axons and growth cones of motoneurons. / In kultivierten Motoneuronen eines Maus-Models für die Motoneuronen-Erkrankung Spinale Muskelatrophie (SMA) verursachen verminderte Mengen des Proteins SMN (survival of motoneurons) Schäden im axonalen Wachstum. Dies korreliert mit einer verminderten Menge an β-Aktin kodierender mRNA und β-Aktin Protein. Dies impliziert, dass anterograder Transport und lokale Translation von β-Aktin mRNA für die Motoneuronfunktion notwendig ist. Bislang gab es jedoch keinen direkten Nachweiß funktioneller lokaler Translation in Wachstumskegeln von Motoneuronen. In dieser Arbeit wurde ein lentivirales GFP-basierendes Reporterkonstrukt etabliert, welches lokale Proteinsynthese von β-Aktin mRNA nachweißt. Zeitraffermikroskopie von GFP-vermittelter Fluoerszenzregeneration nach Fotobleichung (fluorescence recovery after photobleaching; FRAP) in lebenden Motoneuronen zeigte, dass β-Aktin in Wachstumskegeln embryonaler Motoneuronen lokal translatiert wird. Interessanterweise wurde die lokale Translation des β-Aktin Reporterkonstrukts differentiell durch verschiedene Laminin-Isoformen reguliert. Dies gibt einen Hinweis, dass Laminin als extrazelluläres Signalmolekül die Regulation der lokalen Translation in Wachstumskegeln reguliert. Die lokale Translation von β-Aktin mRNA war dereguliert wenn Motoneurone eines Mausmodels für die Typ I SMA (Smn-/-;SMN2) analysiert wurden. In situ Hybridisierung bestätigte eine Reduktion von β-Aktin mRNA in den Axonen von Smn-/-;SMN2 Motoneuronen. Die Verteilung der β-Aktin mRNA wurde von verschiedenen Laminin-Isoformen nicht beeinflusst, wie durch in situ Hybridisierung gegen eGFP kodierende Elemente des β-Aktin Reporters bestätigt werden konnte. Im Fall der mRNA für α-Aktin und γ-Aktin Isoformen wurde keine axonale Lokalisierung der endogenen mRNAs festgestellt und das Lokalisierungsmuster dieser mRNAs war durch reduzierte zelluläre SMN Mengen nicht beeinflusst. Zusammenfassend deuten diese Befunde darauf hin, dass die lokale Translation von β-Aktin in Wachstumskegeln von Motoneuronen von Laminin-Signalgebung und von der Menge an SMN Protein abhängt. Motoneurone aus embryonalen Stammzellen sind ein etabliertes in vitro System um biochemische und zelluläre Signalwege zu identifizieren, die in neurodegenerativen Erkrankungen wie SMA betroffen sind. Hier wird ein Protokoll zur Differenzierung und Antikörper-gestützten Anreicherung von Motoneuron aus embryonalen Stammzellen präsentiert, welches im Rahmen dieser Arbeit optimiert wurde. Im Besonderen wird die Herstellung und Reinigung von hochaktivem Sonic Hedgehog (Shh) vorgestellt, welches für die effiziente Differenzierung von embryonalen Stammzellen der Maus notwendig war. Motoneurone aus embryonalen Stammzellen werden in zukünftigen Studien nun große Mengen an zellulärem Material liefern, und somit auf biochemischer Ebene die Identifizierung von krankheitsrelevanten molekularen Komponenten ermöglichen, die in der Regulation der lokalen Proteinsynthese in Axonen und Wachstumskegeln von Motoneuronen involviert sind.

Motoneuron

Maus

Embryo

Proteinsynthese

ddc:570

The role of TrkB and NaV1.9 in activity-dependent axon growth in motoneurons / Die Rolle von TrkB und NaV1.9 in aktivitätsabhängigem Axonwachstum von Motoneuronen

Wetzel, Andrea

January 2013

Während der Entwicklung des Nervensystems lassen sich bei Motoneuronen aktivitätsabhängige Kalziumströme eobachten, die das Axonwachstum regulieren. Diese Form der neuronalen Spontanaktivität sowie das Auswachsen von Axonen sind bei Motoneuronen, die aus Tiermodellen der Spinalen Muskelatrophie isoliert werden, gestört. Experimente aus unserer Arbeitsgruppe haben gezeigt, dass spontane Erregbarkeit und aktivitätsabhängiges Axonwachstum von kultivierten Motoneuronen auch unter Verwendung von Toxinen beeinträchtigt sind, welche die Aktivität von spannungsabhängigen Natriumkanälen blockieren. In diesen Versuchen war die Wirkung von Saxitoxin effizienter als die Wirkung von Tetrodotoxin. Wir identifizierten den Saxitoxin-sensitiven/Tetrodotoxin-insensitiven spannungsabhängigen Natriumkanal NaV1.9 als Trigger für das Öffnen spannungsabhängiger Kalziumkanäle. Die Expression von NaV1.9 in Motoneuronen konnte über quantitative RT-PCR nachgewiesen werden und antikörperfärbungen offenbarten eine Anreicherung des Kanals im axonalen Wachstumskegel sowie an Ranvier'schen Schnürringen von isolierten Nervenfasern wildtypischer Mäuse. Motoneurone von NaV1.9 knock-out Mäusen zeigen reduzierte Spontanaktivität und eine Reduktion des Axonwachstums, welche durch NaV1.9 Überexpression normalisiert werden kann. In Motoneuronen von Smn-defizienten Mäusen konnte keine Abweichung der NaV1.9 Proteinverteilung nachgewiesen werden. Kürzlich wurden Patienten identifiziert, die eine missense-Mutation im NaV1.9 kodierenden SCN11A Gen tragen. Diese Patienten können keinerlei Schmerz empfinden und leiden zudem an Muskelschwäche in Kombination mit einer verzögerten motorischen Entwicklung. Im Rahmen dieser Doktorarbeit konnten molekularbiologische Untersuchungen an Mäusen, welche die Mutation im orthologen Scn11a Gen tragen, zur Aufklärung des Krankheitsmechanismus beitragen. Die Kooperationsstudie zeigte, dass eine gesteigerte Funktion von NaV1.9 diese spezifische Kanalerkrankung auslöst, was die Wichtigkeit von NaV1.9 in menschlichen Motoneuronen unterstreicht. Eine frühere Studie beschrieb an hippocampalen Neuronen, dass die Rezeptortyrosinkinase tropomyosin receptor kinase B (TrkB) den NaV1.9 Kanal öffnen kann. Im Wachstumskegel von Motoneuronen ist TrkB nachweisbar und folglich in räumlicher Nähe zu NaV1.9 zu finden. Um zu prüfen, ob TrkB in die spontane Erregbarkeit von Motoneuronen involviert ist, wurden TrkB knock-out Mäuse untersucht. Isolierte Motoneurone von TrkB knock-out Mäusen weisen eine Reduktion der Spontanaktivität und eine Verringerung des Axonwachstums auf. Ob TrkB und NaV1.9 hierbei funktionell gekoppelt sind, ist Gegenstand künftiger Forschung. / During development of the nervous system, spontaneous Ca2+ transients are observed that regulate the axon growth of motoneurons. This form of spontaneous neuronal activity is reduced in motoneurons from a mouse model of spinal muscular atrophy and this defect correlates with reduced axon elongation. Experiments from our group demonstrated that voltage-gated sodium channel pore blockers decrease spontaneous neuronal activity and axon growth in cultured motoneurons, too. In these experiments, saxitoxin was more potent than tetrodotoxin. We identified the saxitoxin-sensitive/tetrodotoxin-insensitive voltage-gated sodium channel NaV1.9 as trigger for the opening of voltage-gated calcium channels. In motoneurons, expression of NaV1.9 was verified via quantitative RT-PCR. Immuno labelling experiments revealed enrichment of the channel in axonal growth cones and at the nodes of Ranvier of isolated nerve fibres from wild type mice. Motoneurons from NaV1.9 knock-out mice show decreased spontaneous activity and reduced axonal elongation. This growth defect can be rescued by NaV1.9 overexpression. In motoneurons from Smn-deficient mice, NaV1.9 distribution appeared to be normal. Recently, patients carrying a missense mutation in the NaV1.9-encoding gene SCN11A were identified. These patients are not able to feel pain and suffer from muscular weakness and a delayed motor development. Molecular biological work during this dissertation supported the analysis of this mutation in a mouse model carrying the orthologous alteration in the Scn11a locus. The cooperation study confirmed that a gain-of-function mechanism underlies the NaV1.9-mediated channelopathy, thus suggesting a functional role of NaV1.9 in human motoneurons. An earlier study showed in hippocampal neurons that the receptor tyrosine kinase tropomyosin receptor kinase B (TrkB) can open the NaV1.9 channel. TrkB is localized in growth cones of motoneurons and subsequently found in close proximity to NaV1.9. In order to proof whether TrkB is involved in spontaneous excitability in motoneurons, TrkB knock-out mice were analysed. Isolated motoneurons from TrkB knock-out mice show a reduced spontaneous activity and axon elongation. It remains to be studied whether TrkB and NaV1.9 are functionally connected.

Motoneuron

Axon

Wachstum

Natriumkanal

ddc:570

Initial characterization of mouse Syap1 in the nervous system: Search for interaction partners, effects of gene knockdown and knockout, and tissue distribution with focus on the adult brain / Erste Charakterisierung des Maus-Syap1 im Nervensystem: Suche nach Interaktionspartnern, Auswirkungen von Gen-Knockdown und-Knockout sowie Untersuchungen über die Verteilung im Gewebe mit Fokus auf das adulte Gehirn

Schmitt, Dominique

January 2017

The synapse-associated protein of 47 kDa (Sap47) in Drosophila melanogaster is the founding member of a phylogenetically conserved protein family of hitherto unknown molecular function. Sap47 is localized throughout the entire neuropil of adult and larval brains and closely associated with glutamatergic presynaptic vesicles of larval motoneurons. Flies lacking the protein are viable and fertile and do not exhibit gross structural or marked behavioral deficiencies indicating that Sap47 is dispensable for basic synaptic function, or that its function is compensated by other related proteins. Syap1 - the mammalian homologue of Sap47 - was reported to play an essential role in Akt1 phosphorylation in various non-neuronal cells by promoting the association of mTORC2 with Akt1 which is critical for the downstream signaling cascade for adipogenesis. The function of Syap1 in the vertebrate nervous system, however, is unknown so far. The present study provides a first description of the subcellular localization of mouse Syap1 in cultured motoneurons as well as in selected structures of the adult mouse nervous system and reports initial functional experiments. Preceding all descriptive experiments, commercially available Syap1 antibodies were tested for their specificity and suitability for this study. One antibody raised against the human protein was found to recognize specifically both the human and murine Syap1 protein, providing an indispensable tool for biochemical, immunocytochemical and immunohistochemical studies. In the course of this work, a Syap1 knockout mouse was established and investigated. These mice are viable and fertile and do not show obvious changes in morphology or phenotype. As observed for Sap47 in flies, Syap1 is widely distributed in the synaptic neuropil, particularly in regions rich in glutamatergic synapses but it was also detected at perinuclear Golgi-associated sites in certain groups of neuronal somata. In motoneurons the protein is especially observed in similar perinuclear structures, partially overlapping with Golgi markers and in axons, dendrites and axonal growth cones. Biochemical and immunohistochemical analyses showed widespread Syap1 expression in the central nervous system with regionally distinct distribution patterns in cerebellum, hippocampus or olfactory bulb. Besides its expression in neurons, Syap1 is also detected in non-neuronal tissue e.g. liver, kidney and muscle tissue. In contrast, non-neuronal cells in the brain lack the typical perinuclear accumulation. First functional studies with cultured primary motoneurons on developmental, structural and functional aspects reveal no influence of Syap1 depletion on survival and morphological features such as axon length or dendritic length. Contrary to expectations, in neuronal tissues or cultured motoneurons a reduction of Akt phosphorylation at Ser473 or Thr308 was not detected after Syap1 knockdown or knockout. / Das Synapsen-assoziierte Protein von 47 kDa (Sap47) in Drosophila melanogaster ist das Gründungsmitglied einer phylogenetisch konservierten Proteinfamilie von unbekannter molekularer Funktion. Sap47 ist im gesamten Neuropil des adulten und larvalen Gehirns lokalisiert und mit glutamatergen, präsynaptischen Vesikeln in larvalen Motoneuronen assoziiert. Fliegen, denen das Protein fehlt, sind lebensfähig und fruchtbar und weisen keine schwerwiegenden strukturellen oder ausgeprägten verhaltensbezogenen Defizite auf, was darauf hinweist, dass Sap47 für eine basale synaptische Funktion entbehrlich ist beziehungsweise das Fehlen seiner Funktion durch andere, eventuell verwandte Proteine, kompensiert werden kann. Über Syap1 - das Säugetierhomolog von Sap47 - wurde berichtet, dass es in verschiedenen nicht-neuronalen Zellen eine essentielle Rolle in der Akt1 Phosphorylierung spielt, indem es die Assoziation von mTORC2 und Akt1 begünstigt, welche für den nachgeschalteten Signalweg bei der Adipogenese essentiell ist. Die Funktion von Syap1 im Vertebraten-Nervensystem ist dagegen bislang unbekannt. Die vorliegende Studie liefert die Erstbeschreibung von neuronalem Syap1 über die subzelluläre Lokalisation des Proteins in kultivierten Motoneuronen sowie die Verteilung in ausgewählten Strukturen des adulten Nervensystems der Maus und beschreibt initiale funktionelle Experimente. Allen beschreibenden Experimenten voran, wurden kommerziell erhältliche Syap1 Antikörper auf ihre Spezifität und Tauglichkeit für diese Studie getestet. Einer der Antikörper, der gegen das humane Protein hergestellt wurde, erkennt spezifisch sowohl das humane, als auch das murine Syap1 Protein und stellt somit ein unentbehrliches Werkzeug für alle biochemischen, immunzytochemischen und immunhistochemischen Untersuchungen dar. Im Zuge der Arbeit wurde eine Syap1-Knockout Maus untersucht, welche vital und fruchtbar ist und keine offensichtlichen Veränderungen in ihrem morphologischen Phänotyp aufweist. Wie auch Sap47 in Fliegen, ist Syap1 im synaptischen Neuropil weit verbreitet, insbesondere in Regionen, die reich an glutamatergen Synapsen sind, aber es wurde auch in einer deutlichen, Golgi-assoziierten Akkumulation in bestimmten Gruppen neuronaler Zellkörper beobachtet. In Motoneuronen wurde das Protein besonders in ähnlichen perinukleären Strukturen detektiert, welche zum Teil mit Golgi Markern überlappen und zudem in Axonen, Dendriten und Wachstumskegeln detektiert. Wie biochemische und immunhistochemische Untersuchungen ergaben, zeigt das Syap1 Protein eine weit verbreitete Expression im zentralen Nervensystem mit Regionen-spezifischem Verteilungsmuster wie es beispielsweise im Kleinhirn, dem Hippocampus oder dem olfaktorischen Bulbus beobachtet wurde. Neben der Expression in Neuronen wurde Syap1 auch in nicht neuronalen Geweben wie der Leber, Niere und im Muskel detektiert. Nicht-neuronalen Zellen im Gehirn fehlte dagegen die typische perinukleäre Akkumulation in immunhistochemischen Färbungen. Erste funktionelle Studien mit kultivierten primären Motoneuronen über entwicklungsbezogene, strukturelle und funktionelle Gesichtspunkte ergaben keinen Einfluss einer Syap1 Depletion auf das Überleben oder morphologische Merkmale wie Axon- oder Dendritenlänge. Entgegen den Erwartungen, wurde nach Syap1 Knockdown oder Knockout in neuronalem Gewebe oder kultivierten Motoneuronen keine Reduktion in der Akt1 Phosphorylierung an Ser473 oder Thr308 detektiert.

Synapse

Nervensystem

Motoneuron

Golgi-Apparat

ddc:570

Whole transcriptome profiling of compartmentalized motoneurons / Globale Transkriptomanalyse von kompartimentierten Motoneuronen

Saal, Lena

January 2017

Spinal muscular atrophy and amyotrophic lateral sclerosis are the two most common devastating motoneuron diseases. The mechanisms leading to motoneuron degeneration are not resolved so far, although different hypotheses have been built on existing data. One possible mechanism is disturbed axonal transport of RNAs in the affected motoneurons. The underlying question of this study was therefore to characterize changes in transcript levels of distinct RNAs in cell culture models of spinal muscular atrophy and amyotrophic lateral sclerosis, especially in the axonal compartment of primary motoneurons. To investigate this in detail we first established compartmentalized cultures of Primary mouse motoneurons. Subsequently, total RNA of both compartments was extracted separately and either linearly amplified and subjected to microarray profiling or whole transcriptome amplification followed by RNA-Sequencing was performed. To make the whole transcriptome amplification method suitable for compartmentalized cultures, we adapted a double-random priming strategy. First, we applied this method for initial optimization onto serial dilutions of spinal cord RNA and later on to the compartmentalized motoneurons. Analysis of the data obtained from wildtype cultures already revealed interesting results. First, the RNA composition of axons turned out to be highly similar to the somatodendritic compartment. Second, axons seem to be particularly enriched for transcripts related to protein synthesis and energy production. In a next step we repeated the experiments by using knockdown cultures. The proteins depleted hereby are Smn, Tdp-43 and hnRNP R. Another experiment was performed by knocking down the non-coding RNA 7SK, the main interacting RNA of hnRNP R. Depletion of Smn led to a vast number of deregulated transcripts in the axonal and somatodendritic compartment. Transcripts downregulated in the axons upon Smn depletion were especially enriched for GOterms related to RNA processing and encode proteins located in neuron projections including axons and growth cones. Strinkingly, among the upregulated transcripts in the somatodendritic compartment we mainly found MHC class I transcripts suggesting a potential neuroprotective role. In contrast, although knockdown of Tdp-43 also revealed a large number of downregulated transcripts in the axonal compartment, these transcripts were mainly associated with functions in transcriptional regulation and RNA splicing. For the hnRNP R knockdown our results were again different. Here, we observed downregulated transcripts in the axonal compartment mainly associated with regulation of synaptic transmission and nerve impulses. Interestingly, a comparison between deregulated transcripts in the axonal compartment of both hnRNP R and 7SK knockdown presented a significant overlap of several transcripts suggesting some common mechanism for both knockdowns. Thus, our data indicate that a loss of disease-associated proteins involved in axonal RNA transport causes distinct transcriptome alterations in motor axons. / Spinale Muskelatrophie und Amyotrophe Lateralsklerose zählen zu den beiden häufigsten und schwersten Motoneuronerkrankungen. Der zugrunde liegende Mechanismus beider Krankheiten ist bis heute nicht geklärt, dennoch werden verschiedene Theorien diskutiert. Ein möglicher Grund ist ein gestörter axonaler Transport von RNAs in den betroffenen Motoneuronen. Daraus folgernd ergab sich die zugrunde liegende Frage dieser Arbeit, ob Veränderungen in den Transkriptleveln bestimmter RNAs unter krankheitsähnlichen Bedingungen vor allem im axonalen Kompartiment von primären Maus-Motoneuronen beobachtet werden können. Um die Fragestellung genauer zu untersuchen, etablierten wir zuerst kompartimentierte Kulturen von primären Motoneuronen. Darauffolgend haben wir die totale RNA aus beiden Kompartimenten separat extrahiert und entweder diese linear amplifiziert und zur Microarrayanalyse gegeben oder wir führten eine Amplifikation des kompletten Transkriptoms mit anschließender RNA-Sequenzierung durch. Um die Amplifikation des kompletten Transkriptoms auch für die kompartimentierten Kulturen geeignet zu machen, verwendeten wir eine doublerandom priming Strategie und haben diese entsprechend angepasst. Zuerst wendeten wir die Methode an Serienverdünnungen von RNA aus dem Rückenmark an, um die Methode zu optimisieren. Später benutzten wir die Methode ebenfalls für kompartimentierte Motoneurone. Schon die Analyse der Wildtyp-Daten lieferte interessante Ergebnisse. Erstens, die Zusammensetzung der RNA in Axonen war höchst ähnlich zu der im somatodendritischen Kompartiment. Zweitens, in Axonen scheinen speziell Transkripte angereichert zu sein, welche mit Proteinsynthese und Energieproduktion in Verbindung stehen. In einem nächsten Schritt wurden dann die Experimente unter Verwendung von Knockdown-Kulturen wiederholt. Die Proteine, die dabei vermindert wurden waren Smn, Tdp-43 und hnRNP R. Ein weiteres Experiment wurde durchgeführt indem die nicht-codierende RNA 7SK verringert wurde. Die Depletion von Smn führte zu einer hohen Anzahl an deregulierten Transkripten sowohl im axonalen, als auch im somatodendritischen Kompartiment. Transkripte, die im axonalen Kompartiment nach Smn Depletion verringert waren, waren überwiegend für GOTerms angereichert, welche mit RNA Prozessierung in Verbindung stehen oder welche Proteine codieren, die in neuronalen Fortsätzen, einschließlich Axon und Wachstumskegel lokalisiert sind. Bemerkenswert ist, dass wir unter den hochregulierten Transkripten im somatodendritischen Kompartiment überwiegend MHC Klasse I Transkripte gefunden haben. Dies könnte eine mögliche neuroprotektive Rolle dieser Transkripte annehmen lassen. Im Gegensatz zu den Ergebnissen beim Smn Knockdown fanden wir beim Tdp-43 Knockdown ebenfalls eine große Anzahl an herunterregulierten Transkripten im axonalen Kompartiment, diese sind allerdings überwiegend mit Funktionen in der Transkriptionsregulierung und beim RNA Splicing assoziiert. Die Ergebnisse des hnRNP R Knockdowns waren ebenfalls unterschiedlich. Bei diesem fanden wir die herunteregulierten Transkripte im axonalen Kompartiment überwiegend mit einer Regulierung der synaptischen Übertragung sowie mit Nervenimpulsen assoziiert. Interessanterweise zeigte ein Vergleich der deregulierten Transkripte sowohl im axonalen Kompartiment vom hnRNP R Knockdown, als auch vom 7SK Knockdown eine signifikante Übereinstimmung mehrerer Transkripte. Dies lässt einen teilweise gemeinsamen Mechanismus für beide Genprodukte vermuten. Somit deuten unsere Daten darauf hin, dass ein Verlust von krankheitsassoziierten Proteinen, die eine Rolle beim axonalen RNA-Transport spielen, zu verschiedenen Transkriptomveränderungen in Axonen von Motoneuronen führt.

Axon

Motoneuron

Spinale Muskelatrophie

ddc:616

CONTRIBUTIONS OF EAG PROTEIN TO NEURONAL EXCITABILITY IN IDENTIFIED THORACIC MOTONEURONS OF DROSOPHILA

Srinivasan, Subhashini

January 2010

Diversity in the expression of ion channel proteins among neurons allows a wide range of excitability, growth and functional regulation. Ether-a-go-go (EAG), a member of the voltage-gated K+ channels, was characterized by spontaneous firing in nerve terminals and enhanced neurotransmitter release. In situ whole-cell patch-clamp recordings performed from the somata of Drosophila larval thoracic aCC motoneurons revealed spontaneous spike-like events in eag mutants. Spontaneous events were absent in wild type motoneurons. Spikes evoked by somatic current injection in to the cell body were not altered and comparable to wild type. Spontaneous spike-like events could be due to increased synaptic drive or altered intrinsic excitability of the motoneuron. Reduction of EAG function with selective expression of eag double stranded RNAi transgene in motoneurons only did not cause spontaneous spike-like events or alter evoked firing. This suggests increased synaptic drive contributes to spontaneous events.Both transient and sustained voltage-activated K+ currents, each with Ca++-sensitive (IA(Ca) and IK(Ca)) and Ca++ -insensitive components (IA and IK), were isolated in thoracic aCC motoneurons. In wild type motoneurons, IA was larger than IA(Ca). Conversely, IK(Ca) was larger than IK. Both eag mutants and eag RNAi expression resulted in a decrease in IA , IK and a slow sustained K+ current. Further, EAG and Shal demonstrate a potential functional interaction and contribute to IA. The voltage sensitivity for inactivation was reduced in Shal only and EAG-Shal double knock down compared to controls and EAG only knock down. In addition, a Ca++ sensitive EAG dependent K+ current was blocked by cAMP. Thus, both voltage-dependent and modulatory functions of EAG influence excitability in motoneurons.Firing properties and K+ currents distinguish aCC motoneurons in thoracic segments, T1 and T3. T3aCC had a shorter delay to spike, higher input resistance and were more easily recruited than T1aCC. T1aCC had a larger IA than T3aCC, but comparable IA(Ca). IK(Ca) was larger in T3aCC compared to T1aCC. These differences reflect cell-specific ion channel distribution that could contribute to patterned segmental motor output.

Drosophila

Excitability

Motoneuron

Patch-clamp

Potassium channel

The Role of Voltage Dependent Calcium Channels in Identified Motoneurons During Fictive Locomotor Behavior

Worrell, Jason Walter

January 2008

The primary goal of this work was to examine the role of voltage-dependent Ca2+ channels in regulating the output of larval Drosophila motoneurons functioning within an intact network. To accomplish this goal, two major aims were addressed: 1. To determine whether larval Drosophila motoneurons express voltage-dependent Ca2+ channels in their central processes, and further, to determine the genes responsible. 2. To determine the role of centrally expressed voltage-dependent Ca2+ channels in the regulation of motoneuron output as motoneurons receive behaviorally relevant input from the locomotor network. To address these goals, genetic tools available in Drosophila were used along side in situ patch clamp techniques from larval motoneurons.Using whole cell voltage-clamp techniques in situ, we have shown that two identified motoneurons, aCC and RP-2, carry voltage-dependent currents recorded from the soma. Dmca1D, the L-type like channel in Drosophila, is primarily responsible for this current. Expressing Dmca1D RNAi in aCC and RP-2, as the preparation displayed fictive bouts of locomotion, caused an increase in burst duration in both RP-2 and aCC as well as an increase in the number of action potentials fired per burst. Additionally, the afterhyperpolarization between spikes was greatly reduced and spiking became less regular. This work indicates a role for Dmca1D in the processing of synaptic information in Drosophila motoneurons aCC and RP-2.

calcium

Drosophila

locomotion

motoneuron

voltage gated

The activation of persistent inward currents in feline spinal motoneurons is noise and location-dependent

Garg, ANIRUDHA

07 December 2009

The ability to control the output for a given input is an important feature of neurons as it allows them to respond to a multitude of inputs via the production of a scalable output. Using compartmental models of morphologically accurate reconstructions of feline spinal motoneurons, we examined the ability for motoneurons of the feline spinal cord to alter their input-output properties via the variable activation of persistent inward currents (PICs) due to L-type Ca2+ channels located in hotspots on their dendrites. Traditionally, the activation of PICs is thought to be a threshold-dependent event reliant on the response of hotspots of these channels to a depolarization beyond a specific local voltage. Converse to this belief, we have found that the response of spinal motoneuron PICs is not exclusively voltage-dependent but is also reliant on time-varying fluctuations in membrane potential (noise). Moreover, we show that the activation of PICs in motoneurons is dependent on the location of these dendritic hotspots, which is correlated with cell size. Small motoneurons exhibited delayed activation in response to time-varying input and large motoneurons exhibited no change. The activity of the models was measured via discharge frequency which was due to the activation of dendritically located synapses either firing in a time-averaged (tonic) manner or a Poisson-distributed spike train (transient) with the same overall conductance and distribution as the tonic synapses. These results demonstrate a novel mechanism for the activation characteristics of PICs in motoneurons and, in turn, the ability for the neuron to intrinsically alter its input-output properties. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2009-11-30 14:10:24.905

motoneuron

noise

PIC

calcium

model

neuron

Mapping the distribution of HCN1-subunit containing channels on the dendritic trees of trapezius motoneurons

Zhao, Ethan

09 August 2012

Voltage-dependent channels on the dendrites of motoneurons provide additional current that amplifies or dampens synaptic current en route to the soma. The specific consequences will depend on the density and distribution of the voltage-dependent channels. HCN channels generate a positive inward current in response to hyperpolarization. HCN channels are responsible for a resonance phenomenon in motoneurons where inputs of certain frequencies are preferentially amplified. Modelling studies indicate that this resonance behaviour only occurs if HCN channels are uniformly distributed on the dendritic tree. However, the distribution of HCN channels on the dendrites of motoneurons is unknown. Furthermore, current techniques for measuring channel density on dendrites suffer from methodological limitations that prevent sampling on a scale necessary to map the distribution of voltage-dependent channels across the dendritic tree. The goal of the present study is to develop a high throughput method for measuring the membrane-associated density of voltage-dependent channels using immunohistochemical, confocal and three-dimensional image analysis techniques. Secondly, the proximal to distal distribution of membrane-associated channels formed by the HCN1-subunit on the dendritic trees of trapezius motoneurons in the adult feline will be compared. Antidromically identified motoneurons innervating the trapezius muscle were intracellularly stained in order to visualize the entire dendritic tree. HCN1-subunit containing channels were labeled with a specific antibody. Dendritic segments (n=27 to 92) of ten trapezius motoneurons at different distances from the soma were acquired using confocal microscopy and rendered into a three-dimensional volume. The perimeter of the intracellular stain was used to define the membrane-cytoplasmic border. Analysis of the HCN1 immunoreactivitywas constrained to this perimeter. This technique provides a means of extracting membrane-associated HCN1 labeling and therefore the functional distribution of HCN1 channels. The density of membrane-associated HCN1 immunoreactvity across the dendritic tree was either uniform or increased with distance from the soma among the ten trapezius motoneurons. The increase in HCN1 density with distance from the soma was inversely related to the density of HCN1 on the soma and proximal dendrites. Lastly, the change in HCN1 density with distance from the soma was inversely related to the total input conductance of the motoneuron. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2012-08-01 13:59:32.403

Immunohistochemistry

Subthreshold Resonance

HCN1

Ih

Motoneuron

The regulation of synaptic efficacy at regenerated and cultured neuromuscular junctions

Chipman, Peter H.

02 August 2012

The neuromuscular junction (NMJ) is a synapse formed between a motoneuron and a muscle fiber which transmits the signals required to initiate muscle contraction. The functional state of the NMJ is intimately tied to the structure and function of the motoneuron, such that reductions in postsynaptic activity retrogradely stimulate sustained reorganization of presynaptic motor terminals in an attempt to maintain normal contractile output. In the adult, these plastic changes occur most notably as regenerative responses following traumatic injury and during the progression of motoneuron diseases (MNDs), and can contribute to a considerable amount of functional repair. However, limitations to the regeneration capacity of motoneurons place an upper limit on the effectiveness of endogenous repair mechanisms and can restrict the extent of functional recovery. Using a combination of immunofluorescence, sharp electrode electrophysiology and live labeling of synaptic vesicle recycling during various forms of synaptic growth and regeneration in vivo and in vitro, I have identified that the neural cell adhesion molecule (NCAM) is a key regulator of the regenerative capacity of motoneurons. In vivo experiments revealed that NCAM influences the maturation and stabilization of regenerated synapses via the recruitment and recycling of synaptic vesicles necessary for effective synaptic transmission. The presence of both pre- and post-synaptic NCAM were necessary to maintain the abundance of recycling synaptic vesicles at regenerated synapses, demonstrating a coordinated influence of these molecules in regenerative synaptic plasticity in vivo. To accurately assess the regenerative potential of motoneurons in vitro, it was necessary to develop a system which could reliably and consistently generate mature NMJs amenable to experimental investigation. Motoneurons differentiated from embryonic stem cells were grown for 3-5 weeks in co-culture with muscle fibers and generated mature NMJs which possessed morphological and functional criteria consistent with NMJs formed in vivo. NMJs formed by NCAM-/- motoneurons did not mature and were found to exhibit deficits consistent with their in vivo counterparts. These studies have revealed that NCAM is a key mediator of regenerative plasticity at the NMJ and may be a target for efforts to enhance endogenous repair following traumatic injury or during the progression of neurodegenerative disease.

Inhibitory Control of Muscle Activity in Sleep

Brooks, Patricia

29 August 2011

In this thesis, I examined the inhibitory control of REM sleep motor activity using both a pharmacological rat model and a genetic mouse model. I characterized the role for GABA and glycine in mediating the REM-specific suppression of muscle activity as well as their involvement in regulating the phasic muscle twitches that punctuate this atonia. Based on four specific research objectives, the following conclusions were drawn: 1. REM atonia is not directly mediated by glycinergic or GABAA-mediated inhibition. These data refute the prevailing hypothesis that REM atonia is caused by glycinergic inhibition. These receptors are, however, important in the regulation of phasic muscle twitch activity. 2. GABAB receptors can modulate REM atonia but only when acting in concert with GABAA and glycine receptors. Blockade of all three receptor types results in a partial reversal of REM atonia, suggesting a functional interaction is occurring between these receptors during REM sleep. 3. The phasic glycinergic/GABAA-mediated inhibitory drive present in REM sleep regulates the temporal pattern of phasic twitch activity that is seen across this state. I hypothesize that this progressively decreasing inhibitory input counteracts a gradually increasing excitatory input to shape the temporal distribution of muscle twitches across REM sleep. 4. A loss of normal inhibitory function may play a causal role in the pathology of REM sleep behaviour disorder (RBD), the sleep disorder characterized by excessive motor activity in REM sleep.

sleep

motoneuron

glycine

GABA

0317

0719